A method and apparatus for converting thermal energy to mechanical energy. Operating on a thermodynamic cycle of isentropic compression, isothermal expansion, isentropic expansion and finally constant pressure cooling and contraction, an external heat engine utilizes a heat exchanger carrying heat from an external energy source to the working parts of the engine. Apparatus and methods are disclosed for engine piston timing, such that during isothermal expansion, each unit angular rotation of a drive shaft results in the capture of a constant, unit amount of working fluid expansion energy. Thus, the amount of energy captured during each unit angular rotation of apparatus drive shaft is a constant. Timing the working fluid expansion and fluid flow assures that the working fluid undergoes isothermal expansion, regardless of the quantum of heat energy applied. The modulation of heat input to the heat exchanger results in an automatic modulation of engine speed.
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7. A method for timing the operation of a thermal engine exploiting a thermodynamic cycle including an isothermal expansion step, comprising:
isothermally expanding a working fluid against a moveable piston to turn a loaded shaft through at least one angular rotation;
determining a required total engine volume v as a function of a shaft angle θ, using the formulae
dE(θ)/dθ=P·dV=Constant and V=VieK/ wherein P is pressure and E is the energy extracted from the expanding working fluid, engine volume v is a function of the engine shaft angle θ, K is an angular power increment, θ1 is an isothermal begin angle, and vi is the engine volume at the start of isothermal expansion; and
determining a piston position as a function of shaft angle during isothermal expansion.
1. A method for operating a thermal engine to convert thermal energy to mechanical energy, comprising the steps of:
providing a unit mass of working fluid at an ambient temperature and an ambient pressure;
isentropically compressing the unit mass of working fluid to a higher temperature and a higher pressure;
isothermally expanding the unit mass to a first subsequent volume;
uniformly adding heat energy to the unit mass of working fluid by moving the unit mass past a heat exchanger while maintaining a constant reynolds number through the heat exchanger;
isentropically expanding the unit mass of working fluid to a second subsequent volume;
driving with the isothermally expanding working fluid a first piston and a second piston in respective cylinders, thereby turning a shaft through at least one angular rotation;
timing the driving of the first piston and the second piston such that a substantially equal amount of working fluid expansion energy is used for each angular rotation of the shaft; and
exhausting at least a portion of the unit mass of working fluid;
wherein the positions of the pistons in the cylinders during isothermal expansion are a function of a shaft rotation angle.
9. A thermal engine for converting thermal energy to mechanical energy, comprising:
means for drawing a unit mass of working fluid into a compression chamber at an ambient temperature and an ambient pressure, comprising:
a compression piston slidably movable within a compression cylinder; and
a transfer piston slidably moveable within a transfer cylinder, said transfer cylinder in fluid communication with said compression cylinder;
means for iseniropically compressing said unit mass of working fluid to a higher temperature and a higher pressure, comprising;
said compression piston slidably movable within said compression cylinder; and
said transfer piston slidably moveable within a transfer cylinder in fluid communication with said compression cylinder;
a heat exchanger, external to the working fluid, for uniformly adding heat energy to said unit mass while isothermally expanding the unit mass of working fluid to a first subsequent volume, wherein said compression piston is slidably movable in said compression cylinder to push at least a portion of said unit mass past said heat exchanger while maintaining a constant reynolds number through said heat exchanger;
a drive shaft in operative connection with said pistons, whereby isothermally expanding working fluid causes said shaft to turn through at least one angular rotation;
means for isentropically expanding said unit mass to a second subsequent volume, comprising said compression piston moving within said compression cylinder; and
a valve for exhausting working fluid from the engine;
wherein positions of said pistons in said cylinders during isothermal expansion are a function of a rotation angle of said drive shaft.
2. The method of
3. The method of
dE(θ)/dθ=P·dV=Constant and V=VieK/ wherein P is pressure and E is the energy extracted from the expanding working fluid, engine volume v is a function of the engine shaft rotation angle θ, K is an angular power increment, θ1 is a shaft angle at the beginning of isothermal expansion, and vi is an engine volume at the start of isothermal expansion.
4. The method of
5. The method of
choosing a constant reynolds number value Re;
defining with the first piston and its corresponding cylinder a first working chamber; and
calculating a first working chamber volume v1 using the formulae
and
V=VieK/ wherein Um is mean flow velocity, μ is the thermal diffusivity of the working fluid, ρ is the density of the working fluid, and L is the characteristic length of the heat exchanger.
6. The method of
defining with the second piston and is corresponding cylinder a second working chamber; and
determining the position of the second piston using the formula
V=V1+v2+Dead_Volume wherein v1 is the first working chamber volume, v2 is a second working chamber volume, and Dead_Volume is the un-swept volume in the engine, including the heat exchanger volume.
8. The method of
10. The engine of
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This application claims the benefit of the filing of U.S. provisional application Ser. No. 60/801,029, filed on 17 May 2006, and the specification thereof is incorporated herein by reference. This application also is related to utility application Ser. No. 10/982,167, filed 4 Nov. 2004, now issued as U.S. Pat. No. 7,284,372, entitled “Method and Apparatus for Converting Thermal Energy to Mechanical Energy,” the entire contents of which is incorporated by reference herein.
1. Field of the Invention (Technical Field)
The present invention relates to engines, specifically to an engine utilizing an improved method for using external heat to heat a unit mass of working fluid and thereby convert the thermal energy to mechanical energy, where the unit mass is later expelled and a new unit mass of working fluid is introduced to repeat the cycle.
2. Background Art
Rudolf Diesel originally identified and developed a thermodynamic cycle similar to the cycle disclosed in the referenced co-pending United States patent application using internal isothermal combustion. However, the “Diesel cycle” is known today as constant pressure combustion, as difficulties in achieving internal isothermal combustion resulted in the general abandonment of the former concept. Seminal backround for Deisel's work is found in U.S. Pat. No. 542,846, issued 16 Jul. 1895. The engine and thermodynamic cycle presently disclosed herein are referred to as the “Crow Thermodynamic Cycle” and the “Crow Cycle Engine.”
The present specification is related to the disclosure provided by this applicant in his co-pending U.S. patent application Ser. No. 10/982,167, published on 4 May 2006 as U.S. Patent App. Pub. No. 20060090467A1. The prior application is not deemed “prior art,” but reference is made thereto as useful background information; the applicant has developed several significant improvements to that engine and methodology which are offered hereinafter.
A method and apparatus for converting thermal energy to mechanical energy. Operating on a little utilized thermodynamic cycle of isentropic compression, isothermal expansion, isentropic expansion and finally constant pressure cooling and contraction, an external heat engine utilizes a heat exchanger carrying heat from an external energy source to the working parts of the engine. Pistons and cylinders are activated by appropriate means to adiabatically compress the working fluid, for example ambient air, to transfer the mass of the air through a heat exchanger to accomplish isothermal expansion followed by adiabatic expansion and, finally, exhaust the air to ambient to allow for constant pressure cooling and contraction. Energy is added to the working fluid and extracted from the engine during isothermal expansion, whereby the energy of compression is added by a flywheel or other appropriate energy storage means.
More specifically, means and methods are disclosed for timing the working fluid expansion and fluid flow to best assure that the working fluid undergoes isothermal expansion, regardless of the quantum of heat energy applied. The modulation of heat input to the heat exchanger results in an automatic modulation of engine speed. To accomplish the desired working fluid expansion, the piston timing is designed such that during isothermal expansion, each and every unit angular rotation of a drive shaft results in the capture of a constant, unit amount of working fluid expansion energy. Thus, the amount of energy captured during each unit angular rotation of apparatus drive shaft is a constant.
Several objects and advantages of the present invention are: (1) To provide a method and apparatus for implementing the Crow Thermodynamic Cycle to convert thermal energy to mechanical energy; (2) To provide a method for determining the timing of the expansion of the working fluid and flow through the heat exchanger; (3) To provide a method for using the expansion timing and fluid flows to determine the timing of the cooperating pistons; (4) To provide an engine that can utilize the Crow Thermodynamic Cycle and operate over a wide range of speeds and input temperatures; (5) To provide an engine that automatically adapts its speed to the applied input temperature and shaft load, while still operating on the ideal thermodynamic cycle; (6) To provide an engine design where the exact characteristics of the heat exchanger need not be known; (7) To provide an engine with improved specific power; (8) To provide an engine with greater flexibility in heat exchanger design; (9) To provide an engine design allowing the use of standard poppet-style valves; and (10) To provide an engine that is easy to assemble and disassemble and maintain.
There is in accordance with the present invention a method and apparatus for converting thermal energy to mechanical energy using the thermodynamic cycle disclosed in U.S. Pat. No. 7,284,372, while allowing for a wide range of operating parameters, automatic and self regulating speed adjustment, great design flexibility and ease of assembly and maintenance.
Other objects, advantages and novel features, and further scope of applicability of the present invention will be set forth in part in the detailed description to follow, taken in conjunction with the accompanying drawings, and in part will become apparent to those skilled in the art upon examination of the following, or may be learned by practice of the invention. The objects and advantages of the invention may be realized and attained by means of the instrumentalities and combinations particularly pointed out in the appended claims.
The accompanying drawings, which are incorporated into and form a part of the specification, illustrate several embodiments of the present invention and, together with the description, serve to explain the principles of the invention. The drawings are only for the purpose of illustrating a preferred embodiment of the invention and are not to be construed as limiting the invention. In the drawings:
Like numerals and letters are used to label like elements and components depicted throughout the various views.
The present disclosure is of an apparatus and method for converting thermal energy into mechanical energy. Reference is made to a thermodynamic cycle that will sometimes be called the “Crow Thermodynamic Cycle,” the “Crow Cycle” or “the subject cycle.” Also in the course of this disclosure reference will be made to a number of mathematical variables. For convenience, the several variables and their corresponding meanings are set forth in Table 1.
TABLE 1
List of Variables
Tc
Low temperature reached by the working fluid during the
thermodynamic cycle
Th
High temperature reached by the working fluid during the
thermodynamic cycle
TRc
Cold reservoir temperature
TRh
Hot reservoir temperature
TB
Temperature at thermodynamic state B
PA
Pressure at thermodynamic state A
PD
Pressure at thermodynamic state D
VA
Engine volume at thermodynamic state A
Cr
Isentropic compression ratio of the working fluid
Er
Expansion ratio: ending isothermal volume to beginning isothermal
volume
ΔT
Temperature difference between the working fluid and the hot or
cold reservoirs
h
Heat transfer coefficient used in basic heat transfer equation
Q = AhΔT
μ
Thermal diffusivity of a gas
Hxv
Open volume inside heat exchanger
θ
Shaft rotation angle
θ1
Isothermal expansion begin angle
θ2
Isothermal expansion end angle
E
Total energy extracted from gas
ω
Shaft rotational angle
P
Pressure
V
Volume
Re
Reynold's number
Universal gas constant
K
Unit energy taken during each unit rotation of drive shaft
Qiso
Isothermal heat input during one thermodynamic cycle
Um
Mean gas velocity through heat exchanger
L
Characteristic length of the heat exchanger
ρ
Density
V1
Volume in first working chamber
V2
Volume in second working chamber
Vi
Volume at beginning of isothermal expansion
V
Total engine volume
Reference to the foregoing list of variables promotes a facile understanding of the further descriptions below.
Thermodynamic Cycle
A full explanation of the Crow Thermodynamic Cycle, and its exploitation to do work in an engine, is provided in my U.S. Pat. No. 7,284,372. In sum, to exploit the Crow Thermodynamic Cycle, the engine performs the following reciprocating steps, as shown in
Intake of ambient air into the volume in state A of the cycle (part of process step 4);
Adiabatic compression of the air, governed by Cr, to achieve the desired air temperature (process step 1);
Isothermal expansion of the contained gas governed by Er (process step 2);
Adiabatic expansion of the air to ambient air pressure governed by PD=PA (process step 3); and
Exhaust of warm air at ambient pressure to the environment (part of process step 4—i.e., step 1 and step 5 are effectively concurrent process steps).
The cycle begins with a unit of working fluid at an ambient pressure and temperature A (
Still referring to
During Process 3, the working fluid is expanded adiabatically, cooling it to TD as the pressure is reduced to ambient. It is important to recognize that by expanding to PA, the resulting volume VD is greater than the volume VA in state A. This results in a piston stroke that is longer than that required to intake the volume VA. During Process 3, work energy is recovered from the gas as it expands and cools. Process 3 effectively recaptures as much of the energy as possible that is supplied during Process 1. Process 3 of the subject cycle thus is corollary to the regenerative cooling process in conventional Stirling engines.
Notably, the rapid compression and expansion of the working fluid in Processes 1 and 3 have the major benefit of not being limited by the ability of a heat exchanger to transfer heat into or out of the fluid. Rather, the engine is limited only in the mechanical ability of the machinery. It should also be recognized that the energy not recovered in Process 3 represents the Carnot inefficiency inherent in every thermodynamic cycle.
Finally, Process 4, the constant pressure heat rejection process, is achieved by simply rejecting the working gas to the environment at constant pressure, as is done in Otto and Diesel cycle engines. The distinct advantage to this process is that the engine now requires no cold heat exchanger to remove the heat from the warm exhaust air. By dumping the exhaust to ambient at an elevated temperature, the engine is using the atmosphere as a heat exchanger with infinite capacity and eliminating the need for a cooler from the design. An advantage in this change is not only in the elimination of the machinery, but also in allowing for the design of an engine with whatever exhaust temperature is desired (above ambient temperature).
In the previously disclosed versions of processes and apparatuses for exploiting the Crow Thermodynamic Cycle, the flow of working fluid through the heat exchanger, and hence the piston timing, was required to be controlled quite exactly. Required fluid flow was calculated by estimating the convection heat transfer characteristics of the heat exchanger in use. With the known flow and a specified timing of a first piston, the second piston timing was specified. However, it has been found challenging to know with reasonable accuracy the heat transfer characteristics of a heat exchanger under ideal conditions. Under dynamic and changing conditions of an engine, it may be difficult to attempt to predict or model the instantaneous heat transfer to the working fluid.
The ideal expansion ratio and expansion piston timing is a given for a selected engine speed and heat exchanger temperature. A potential problem is that if the heat exchanger model is inaccurate, or if the heat exchanger temperature is inaccurate, then the piston timing likely may be sub-optimal or incorrect. Poor piston timing may result in the engine not operating isothermally as desired. The same is true for engine speed; if the engine is connected to a driven member whose speed must be allowed to fluctuate, then engine operation is likely to be degraded significantly as that speed diverges from the design speed. Thus, the above method of calculating the piston timing gives a solution that is likely to work only in a narrow or “tight” operating regime. If the engine is designed around a tight operating regime, the ramifications of excursions outside of that regime are likely to result in degraded performance.
Also the design of the piston timing in previously disclosed apparatus may have a disadvantage in that the expansion piston remains stationary during much of the operating cycle: intake, exhaust and compression. This adversely affects the specific power output (power output per unit mass), and is a relatively inefficient use of available components.
The following disclosure specifies further improvements developed to overcome the foregoing identified potential shortcomings, to provide an apparatus and method of increased efficiency. Further, the apparatus disclosed herein is easily assembled (and disassembled for repair or maintenance).
Automatic Isothermal Piston Timing
Reference is made to
Correctly timing the working fluid expansion and fluid flow through the heat exchanger 10 is central to achieving the desired isothermal expansion required in the engine. The required fluid expansion and fluid flow determines the angular piston timing in the engine.
The goal of timing the working fluid expansion and fluid flow is to ensure that, under all situations (except perhaps steep transients), the working fluid undergoes isothermal expansion, regardless of the heat applied. The modulation of heat input to the heat exchanger 10 results in an automatic modulation of engine speed.
To accomplish the desired working fluid expansion, the piston timing is designed such that for each and every unit angular rotation of the drive shaft, a constant amount of working fluid expansion energy is realized or extracted. (The net energy out of the gas is positive). Mathematically, if θ is the shaft rotation angle, then
dE(θ)/dθ=Constant
Further, the drive shaft's change in rotational energy can be expressed in terms of pressure and volume:
dE(θ)/dθ=P·dV=Constant
Assuming shaft load on the engine is constant, ensuring dE(θ)/dθ=P·dV=Constant results in constant rotational speed of the engine.
Using the above equations in concert with the ideal gas equation PV=
Knowing the engine volume V as a function of shaft angle, however, is only part of the requirements for isothermal timing. To maintain constant working fluid temperature (isothermal) while expansion energy is being extracted from the working fluid, the constancy of heat input to the working fluid must be assured. Since the heat transfer coefficient h is primarily a function of Reynolds number Re, uniform heat input is achieved by maintaining a constant Reynolds number Re through the heat exchanger 10 as a function of shaft rotation angle θ.
The volume and gas speed through the heat exchanger 10 are thus defined. Using the geometry of the engine to determine the corresponding working chamber volumes V1 and V2, and modest additional calculation known to one skilled in the art, determines the precise position of pistons 40 and 40a during isothermal expansion as a function of θ as desired.
By so defining the piston timing, engine speed may be regulated by the heat input to the heat exchanger 10 and the load applied to the shaft. Each unit angular turn of the shaft results in a unit of energy K of gas expansion. Because the Reynolds number Re is constrained to be constant, as a function of θ, the heat transfer coefficient h is increased or decreased by increasing or decreasing the shaft rotational speed ω. Thus if for a given load and heat exchanger temperature the needed or required gas expansion energy K is greater than the unit heat transfer energy, the engine slows down until the heat transfer into the gas is sufficient to balance with the gas expansion energy K. Alternatively, if the needed, or required gas expansion energy K is less than the unit heat transfer energy, the engine speeds up until the heat transfer into the gas is again balanced with K.
The present discussion of isothermal timing and how it is implemented in the current embodiment does not imply that this is the only acceptable means of implementing the method. Rather, the practitioner chooses the geometry or configuration of the engine, and the desired Reynolds number, and the disclosed method generates the appropriate working chamber volumes needed to achieve the desired Reynolds number.
The foregoing isothermal timing having been discussed conceptually, a brief mathematical description of the method is offered by way of additional disclosure.
Assume air as an ideal gas; PV=
Further, as known in the art, expansion energy E=ΣPΔV, or E=∫PdV
Total specific energy per isothermal expansion process Qiso
Unit energy per unit angular rotation of drive shaft K
Energy taken from drive shaft during each unit angular rotation dE=Kdθ
Energy from isothermal expansion equals heat input dQiso=PdV
Isothermal expansion Qiso=E
∫2Kdθ=∫2PdV; ideal gas P=
Conventionally manipulating the above equation yields the result:
V=VieK/
The equation above gives the engine volume V as a function of engine shaft angle θ. Angular power increment K is derived by dividing total energy E (known because the practitioner is free to and does choose Er; it can be derived by anyone skilled in the art) by the isothermal angle θ2−θ1, with θ1 the isothermal begin angle and θ2 the isothermal end angle. Vi is the engine volume at the start of isothermal expansion.
The foregoing provides a basis for determining generally the piston timing for an isothermal engine. But it provides for only the total volume enclosed in the engine, whereas for an engine according to the present disclosure, the volume in each working chamber 50 and 50a (V1 and V2), with respect to shaft angle θ, must be known.
To solve for specific piston timing, the Reynolds number of the heat exchanger is constrained. The Reynold's number
is maintained constant through the heat exchanger 10 (where Re is a function of shaft angle, θ). Because Re is the primary variable determining heat transfer, holding Re constant also maintains constant heat transfer.
Since heat exchanger length L and the working gas's thermal diffusivity μ are constant, ρUm is the value that must be held constant, with Um meaning mean flow velocity. To determine the piston timing, one must choose a value for Re. Solving for
it is observed that Um and ρ are functions of V1 and V2. Note also that V=V1+V2+Dead_Volume. Dead Volume is a constant, representing the un-swept volume in the engine, including the heat exchanger volume and any volume at the top of the chambers 50, 50a un-swept by pistons 40 or 40a. Thus, one can use the constraints
and V=VieK/
Certain ramifications of the foregoing are recognized. The disclosure above assumes that the load is constant and therefore so is engine speed. Large speed variations occurring during the isothermal expansion phase will cause varying heat flux and heat input to the working fluid, resulting in deviations from the ideal isothermal process. It is expected that with substantial flywheels and multi-cylinder engines, engine speed fluctuation can be minimized to negligence.
Engine speed is caused to vary by increasing the heat exchanger temperature. An increase in heat exchanger temperature increases engine speed while a decrease in temperature decreases engine speed. Moreover, knowledge of the heat transfer characteristics of the heat exchanger 10 under specific operating temperatures is not required to design the piston timing, as the engine speed is self regulating.
The engine can be operated in a transient regime with the temperature of the heat exchanger 10 as the driving factor, with the transient response of the heat exchanger acting as the limiting factor to engine transient response. That is, the faster the heat exchanger increases or decreases temperature, the faster the engine can respond to transient power inputs. Additionally, engine speed and power output have a linear correlation with the temperature difference between the heat exchanger and the working fluid.
This method of isothermal timing can be applied to any engine design utilizing isothermal timing in general, and can be applied to any engine operating on the thermodynamic cycle disclosed in U.S. Pat. No. 7,284,372. Thus, this method can be used in an engine with any number of working chambers using a heat exchanger of any form or design.
An Embodiment of the Engine Apparatus
One preferred embodiment of the apparatus according to this disclosure features a heat exchanger between and above, but in immediate adjency with, parallel cylinders. One embodiment for exploiting the Crow Thermodynamic Cycle is illustrated generally in
Reference is made to
As seen in
Metal foam offers several significant advantages. First, the material offers very high specific surface area (surface area divided by unit volume). Second, relatively high heat transfer coefficients can be achieved with low pressure drop through the foam. A disadvantage to the foam is the low conductivity of the bulk foam material, which can be somewhat alleviated by the inclusion of fins or rods protruding into the foam to act as bulk conductors of heat.
Reference is made to
Returning reference to
Referring jointly to
Because cams 170, 170a, 180 and 180a are fixed to rotate with drive axle 160, the proper design of cams 170, 170a, 180 and 180a results in the exact, coordinated timing of the movement of both pistons 40 and 40a required to cause isothermal expansion.
Engine Sequence and Timing
The engine timing diagram in
The timing diagram,
To make the engine operate, the temperature in the heat exchanger 10 is increased until the engine is able to idle under the power of the applied heat. Referring to
At the start of the cycle angle (a) (
At cycle angle (b) (
With reference to
The process from cycle angles (c) to (e) (
With reference to
The action of shuttling the working fluid between working chambers 50 and 50a through heat exchanger 10 serves to add heat energy to the working fluid while it is expanding. Energy is being removed from the engine by expansion at the same rate it is being added as heat, causing net power output to be positive and net change in enthalpy and temperature of the working fluid to be zero.
Once the first piston 40 has forced all of the working fluid out of working chamber 50 and through the heat exchanger, the second piston 40a piston effectively stops moving while the first piston 40 begins moving downward, drawing working fluid once again through the heat exchanger 10 and into working chamber 50, expanding the total working volume further.
At cycle angle (e) (
All power from the heat source during this cycle has been achieved. The heat input has been converted to mechanical energy such that the temperature has been maintained constant at TB. The piston locations at cycle angle (e) (
At the end of the isothermal process 2 (
As the pistons 40 and 40a continue to move away from the heat exchanger 10, the working fluid expands adiabatically while energy is recovered. With reference to
After adiabatic expansion process 3 (
As the pistons 40 and 40a reach top dead center, both poppet valves 60 and 60a remain open as much as allowable for maximum flow. With reference to
Vibration caused by the eccentric timing of the pistons would be excessive in higher power engines using only two cylinders. Therefore, it is contemplated that a production engine would be made with multiple piston pairs axially opposed and out of phase to cancel vibration. For example, two piston pairs would be disposed axially and opposite one another and with their respective timing phased so to minimize vibration and also to maintain a more steady power generation over one revolution of the engine.
The foregoing is a non-limiting example of the way isothermal timing may be implemented, and does not constrain the mode by which thermodynamic cycle of general embodiments may be implemented. Thus, the present disclosure is merely one means of implementing the method of the invention generally, and the isothermal timing method specifically. In alternative embodiments, multiple pistons, various actuating schemes such as standard automotive crankarms, electromagnetic or hydraulic actuation may be employed.
Although the invention has been described in detail with particular reference to these preferred embodiments, other embodiments can achieve the same results. Variations and modifications of the present invention will be obvious to those skilled in the art and it is intended to cover in the appended claims all such modifications and equivalents. The entire disclosures of all applications, patents, and publications cited above are hereby incorporated by reference.
Patent | Priority | Assignee | Title |
10879679, | Dec 15 2015 | Schneider Electric Industries SAS | Device for cooling hot gases in a high-voltage equipment |
10962012, | Aug 30 2010 | FORUM US, INC | Compressor with liquid injection cooling |
8656712, | Oct 03 2007 | ENERGY TECHNOLOGIES INSTITUTE LLP | Energy storage |
8794941, | Aug 30 2010 | FORUM US, INC | Compressor with liquid injection cooling |
8826664, | Oct 03 2007 | ENERGY TECHNOLOGIES INSTITUTE LLP | Energy storage |
9267504, | Aug 30 2010 | FORUM US, INC | Compressor with liquid injection cooling |
9719514, | Aug 30 2010 | FORUM US, INC | Compressor |
9856878, | Aug 30 2010 | FORUM US, INC | Compressor with liquid injection cooling |
Patent | Priority | Assignee | Title |
3867816, | |||
5016441, | Oct 07 1987 | Heat regeneration in engines | |
5209065, | May 08 1990 | Heat engine utilizing a cycle having an isenthalpic pressure-increasing process | |
5809784, | Mar 03 1995 | Meta Motoren- und Energie-Technik GmbH | Method and apparatus for converting radiation power into mechanical power |
5894729, | Oct 21 1996 | Proe Power Systems, LLC | Afterburning ericsson cycle engine |
6109035, | Mar 13 1997 | Motion control method for carnotising heat engines and transformers | |
7284372, | Nov 04 2004 | Method and apparatus for converting thermal energy to mechanical energy |
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